Abstract
Hydra vulgaris is an emerging model organism for neuroscience due to its small size, transparency, genetic tractability, and regenerative nervous system; however, fundamental properties of its sensorimotor behaviors remain unknown. Here, we use microfluidic devices combined with fluorescent calcium imaging and surgical resectioning to study how the diffuse nervous system coordinates Hydra's mechanosensory response. Mechanical stimuli cause animals to contract, and we find this response relies on at least two distinct networks of neurons in the oral and aboral regions of the animal. Different activity patterns arise in these networks depending on whether the animal is contracting spontaneously or contracting in response to mechanical stimulation. Together, these findings improve our understanding of how Hydra's diffuse nervous system coordinates sensorimotor behaviors. These insights help reveal how sensory information is processed in an animal with a diffuse, radially symmetric neural architecture unlike the dense, bilaterally symmetric nervous systems found in most model organisms.
Highlights
Discovering the fundamental principles of neural activity and behaviors requires studying the nervous systems of diverse organisms
Dashed blue square indicates the region of interest (ROI) used for calcium trace shown in blue
Dashed blue square indicates the region of interest (ROI) used indicates the region of interest (ROI) used for the calcium trace shown in blue
Summary
Discovering the fundamental principles of neural activity and behaviors requires studying the nervous systems of diverse organisms. Transparent, millimeter-sized animals in particular offer a number of advantages for neuroscientists because it is possible to image neural activity throughout the entire nervous system using genetically encoded calcium or voltage-sensitive fluorescent proteins (Broussard et al, 2014; Chen et al, 2013; Lemon et al, 2015; Prevedel et al, 2014; Ahrens et al, 2013; Cong et al, 2017; Kim et al, 2017; Portugues et al, 2014; Vladimirov et al, 2014; Gonzales et al, 2020). Some millimeter-sized animals are compatible with microfluidic devices for precise
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